#include "dosbox/dbopl.h"
#include "dosbox/nukedopl.h"
#include "sound_dbopl.h"

static struct {
        DBOPL::Chip chip;
        struct opl3_chip opl3chip;
        int addr;
        int timer[2];
        uint8_t timer_ctrl;
        uint8_t status_mask;
        uint8_t status;
        int is_opl3;
        int opl_emu;

        void (*timer_callback)(void *param, int timer, int64_t period);
        void *timer_param;
} opl[2];

enum { STATUS_TIMER_1 = 0x40, STATUS_TIMER_2 = 0x20, STATUS_TIMER_ALL = 0x80 };

enum {
        CTRL_IRQ_RESET = 0x80,
        CTRL_TIMER1_MASK = 0x40,
        CTRL_TIMER2_MASK = 0x20,
        CTRL_TIMER2_CTRL = 0x02,
        CTRL_TIMER1_CTRL = 0x01
};

void opl_init(void (*timer_callback)(void *param, int timer, int64_t period), void *timer_param, int nr, int is_opl3,
              int opl_emu) {
        if (!is_opl3 || !opl_emu) {
                DBOPL::InitTables();
                opl[nr].chip.Setup(48000, is_opl3);
                opl[nr].timer_callback = timer_callback;
                opl[nr].timer_param = timer_param;
                opl[nr].is_opl3 = is_opl3;
                opl[nr].opl_emu = opl_emu;
        } else {
                OPL3_Reset(&opl[nr].opl3chip, 48000);
                opl[nr].timer_callback = timer_callback;
                opl[nr].timer_param = timer_param;
                opl[nr].is_opl3 = is_opl3;
                opl[nr].opl_emu = opl_emu;
        }
}

void opl_status_update(int nr) {
        if (opl[nr].status & (STATUS_TIMER_1 | STATUS_TIMER_2) & opl[nr].status_mask)
                opl[nr].status |= STATUS_TIMER_ALL;
        else
                opl[nr].status &= ~STATUS_TIMER_ALL;
}

void opl_timer_over(int nr, int timer) {
        if (!timer) {
                opl[nr].status |= STATUS_TIMER_1;
                opl[nr].timer_callback(opl[nr].timer_param, 0, opl[nr].timer[0] * 4);
        } else {
                opl[nr].status |= STATUS_TIMER_2;
                opl[nr].timer_callback(opl[nr].timer_param, 1, opl[nr].timer[1] * 16);
        }

        opl_status_update(nr);
}

void opl_write(int nr, uint16_t addr, uint8_t val) {
        if (!(addr & 1)) {
                if (!opl[nr].is_opl3 || !opl[nr].opl_emu)
                        opl[nr].addr = (int)opl[nr].chip.WriteAddr(addr, val) & (opl[nr].is_opl3 ? 0x1ff : 0xff);
                else
                        opl[nr].addr = (int)OPL3_WriteAddr(&opl[nr].opl3chip, addr, val) & 0x1ff;
        } else {
                if (!opl[nr].is_opl3 || !opl[nr].opl_emu)
                        opl[nr].chip.WriteReg(opl[nr].addr, val);
                else
                        OPL3_WriteReg(&opl[nr].opl3chip, opl[nr].addr, val);

                switch (opl[nr].addr) {
                case 0x02: /*Timer 1*/
                        opl[nr].timer[0] = 256 - val;
                        break;
                case 0x03: /*Timer 2*/
                        opl[nr].timer[1] = 256 - val;
                        break;
                case 0x04:                        /*Timer control*/
                        if (val & CTRL_IRQ_RESET) /*IRQ reset*/
                        {
                                opl[nr].status &= ~(STATUS_TIMER_1 | STATUS_TIMER_2);
                                opl_status_update(nr);
                                return;
                        }
                        if ((val ^ opl[nr].timer_ctrl) & CTRL_TIMER1_CTRL) {
                                if (val & CTRL_TIMER1_CTRL)
                                        opl[nr].timer_callback(opl[nr].timer_param, 0, opl[nr].timer[0] * 4);
                                else
                                        opl[nr].timer_callback(opl[nr].timer_param, 0, 0);
                        }
                        if ((val ^ opl[nr].timer_ctrl) & CTRL_TIMER2_CTRL) {
                                if (val & CTRL_TIMER2_CTRL)
                                        opl[nr].timer_callback(opl[nr].timer_param, 1, opl[nr].timer[1] * 16);
                                else
                                        opl[nr].timer_callback(opl[nr].timer_param, 1, 0);
                        }
                        opl[nr].status_mask = (~val & (CTRL_TIMER1_MASK | CTRL_TIMER2_MASK)) | 0x80;
                        opl[nr].timer_ctrl = val;
                        break;
                }
        }
}

uint8_t opl_read(int nr, uint16_t addr) {
        if (!(addr & 1)) {
                return (opl[nr].status & opl[nr].status_mask) | (opl[nr].is_opl3 ? 0 : 0x06);
        }
        return opl[nr].is_opl3 ? 0 : 0xff;
}

static void opl2_update_impl(int nr, int16_t *buffer, Bit32s *buffer_32, int samples) {
        int c;

        opl[nr].chip.GenerateBlock2(samples, buffer_32);

        for (c = 0; c < samples; c++)
                buffer[c * 2] = (int16_t)buffer_32[c];
}

void opl2_update(int nr, int16_t *buffer, int samples) {
        #define chunk_size 1024

        int n_chunks;
        int rest;
        int i_chunks;
        Bit32s buffer_32[chunk_size];

        n_chunks = samples / chunk_size;
        rest = samples - n_chunks * chunk_size;
        for(i_chunks = 0; i_chunks != n_chunks; ++i_chunks)
                opl2_update_impl(nr, buffer + i_chunks * chunk_size * 2, buffer_32, chunk_size);
        if(rest != 0)
                opl2_update_impl(nr, buffer + n_chunks * chunk_size * 2, buffer_32, rest);

        #undef chunk_size
}

static void opl3_update_impl(int nr, int16_t *buffer, Bit32s *buffer_32, int samples) {
        int c;

        if (opl[nr].opl_emu) {
                OPL3_GenerateStream(&opl[nr].opl3chip, buffer, samples);
        } else {
                opl[nr].chip.GenerateBlock3(samples, buffer_32);

                for (c = 0; c < samples * 2; c++)
                        buffer[c] = (int16_t)buffer_32[c];
        }
}

void opl3_update(int nr, int16_t *buffer, int samples) {
        #define chunk_size 1024

        int n_chunks;
        int rest;
        int i_chunk;
        Bit32s buffer_32[chunk_size * 2];

        n_chunks = samples / chunk_size;
        rest = samples - n_chunks * chunk_size;
        for(i_chunk = 0; i_chunk != n_chunks; ++i_chunk)
                opl3_update_impl(nr, buffer + i_chunk * chunk_size * 2, buffer_32, chunk_size);
        if(rest != 0)
                opl3_update_impl(nr, buffer + n_chunks * chunk_size * 2, buffer_32, rest);

        #undef chunk_size
}
